JP2003021831A - Liquid crystal display device using fluorescent material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a color liquid crystal display device having high image quality even though the display device has low power consumption and a simplified structure and capable of substantially creating full color. SOLUTION: The color liquid crystal display device provided with a first substrate 2 consisting of a first transparent substrate 4 on which color filters (7R, 7G) and a transparent electrode 10 are successively layered on the inner side, a second substrate 14 disposed opposite to the first substrate 2 and consisting of a second transparent substrate 15 on which an active matrix array including pixel electrodes 16 disposed in a matrix shape on the inner side, a liquid crystal layer 11 encapsulated therebetween and a blue color light emitting means 20 disposed on the side opposite to the liquid crystal layer 11 of the second substrate 14 consists of only the red color filters 7R and the green color filters 7G respectively including the material receiving the light having wavelength except the required wavelength to be excited and emitting the light having required wavelength.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly to a transmissive color liquid crystal display device using a fluorescent material.

[0002]

2. Description of the Related Art With the widespread use of notebook type personal computers and personal digital assistants, demand for color liquid crystal display devices is increasing in place of conventional CRTs. A color liquid crystal display device requires some kind of light source. Therefore, a transmissive liquid crystal generally uses a backlight and a reflective liquid crystal uses natural light or the like.

On the liquid crystal screen, the image appears to the human eye depending on the contrast ratio of the image. Therefore, basically, the brighter the image, the easier it is to see. At present, a transmissive liquid crystal using a backlight is generally used to obtain a clear image, but the power consumption of the backlight is about one half to three times that of the color liquid crystal display device.
Occupy two-thirds. On the other hand, if the backlight is dimmed to reduce power consumption, the sharpness of the image is impaired. Therefore, a color liquid crystal display device that is low in power consumption and easy to see is desired.

For this purpose, for example, JP-A-7-12
Japanese Patent No. 8655 discloses a color liquid crystal display device in which a color filter contains a daytime fluorescent substance. The device is shown in FIG. Each reference numeral of the apparatus will be described. 1 is a first substrate, 2 is a second substrate, 101 is a transparent substrate, and 10 is a transparent substrate.
2 is a color filter layer, 103 is a red fluorescent color filter,
Reference numeral 104 is a green fluorescent color filter, 105 is a blue fluorescent color filter, 106 is a black filter, 114 is a diffusion plate, and 115.
Is a fluorescent tube, 107 is a transparent electrode, 108 is a liquid crystal layer, 109
Is a scanning line, 110 is a switch element, 111 is a pixel electrode,
112 is a transparent substrate, 113 is a light emitting means, and 115 is a fluorescent tube.

As a color filter, as shown in FIG. 9, it is general to use a set of three color filters of a red filter 103, a green filter 104 and a blue filter 105. Red filter 103 and green filter 104
, And one pixel electrode 111 is disposed on the transparent substrate 112 so as to face the blue filter 105. These three picture element electrodes 111 form one set to create a color.

Red, green and blue are 3 in the additive color mixture.
Since it is a primary color, the pixel electrode 111 corresponding to these three primary colors
Allows to create virtually any color while varying the intensity of each color. For example, white is created by mixing all three primary colors. The blue filter 105 is about 400 nm of visible light.
Only light with a wavelength of ~ 500 nm is transmitted, the rest is absorbed and reflected. This is because the filter contains a dye or pigment, absorbs light other than the wavelength of 400 nm to 500 nm, and consumes it as heat energy.

Materials having such optical properties are now
It is called a transmission absorption material.

Similarly, the green filter 104 transmits only light having a wavelength of about 500 nm to 600 nm of visible light and absorbs and reflects the rest, and the red filter 105 has a wavelength of about 600 nm to 700 nm of visible light. Of the light is transmitted, and the rest is absorbed and reflected. Thus, the three filters only transmit light between 400 nm and 700 nm,
Light of other wavelengths is absorbed or reflected, and the absorbed light is consumed as heat energy. In other words, each filter transmits only about one-third of the light, and the remaining two-thirds of the light is transmitted.
The light of the wavelength in the region of is absorbed and consumed by the filter itself,
It is not used as light. A general color liquid crystal display device uses the transmission absorption filter as described above.

Therefore, in the invention of this publication, in the color liquid crystal display device having the above-mentioned structure, the daytime fluorescent substance is mixed with the filters 103 to 105 of the respective colors to create more light. That is, the incident light from the light emitting means 113 is applied to the color fluorescent color filters (103 to 105) containing the daytime fluorescent substance to be transmitted and absorbed, and the absorbed light excites the fluorescent substance, whereby the light is emitted. It was attempted to provide a brighter and lower power consuming color liquid crystal display device by using this light together. It should be noted that in the conventional color liquid crystal display device cited as a conventional example in this publication, a fluorescent color filter is not used as a color filter, and a general absorption / transmission type color filter is used.

However, when the fluorescent substance is included in the color filter as in the invention of the publication, the brightness of the created color is superior to the conventional transmissive absorption type color filter in terms of brightness. Inferior to the transmission absorption filter. This is because the conventional transmissive absorption type color filter is superior in the vividness of color development, although it is inferior in brightness as compared with the color filter containing a fluorescent substance.

Further, according to the invention of this publication, as in the conventional color liquid crystal display device cited in this publication, three color filters of red, green and blue are used as color filters.
The manufacturing complexity is similar to that of the conventional color liquid crystal display device, and it can be said that this point has not been improved.

[0012]

SUMMARY OF THE INVENTION Therefore, the present invention has been made in view of the above circumstances, and it is a color liquid crystal display having a structure with low power consumption, high image quality, and a simple manufacturing process. The purpose is to provide a device.

[0013]

The above object can be achieved by a color liquid crystal display device according to the present invention described below.

That is, according to the first aspect of the present invention, the first substrate is composed of the first transparent substrate on which the color filter and the transparent electrode are sequentially laminated inside, and the first substrate is arranged so as to face the first substrate and A second substrate formed of a second transparent substrate on which an active matrix array including pixel electrodes arranged in a matrix is formed; a liquid crystal layer enclosed between the first substrate and the second substrate; A blue light emitting means disposed on the second substrate on the side opposite to the liquid crystal layer, wherein the color filter is excited by receiving light in a wavelength region other than the required wavelength region, and the desired wavelength is obtained. A color liquid crystal display device comprising only a red filter and a green filter each containing a material for emitting light in a region.

As described above, the color liquid crystal display device according to the present invention does not use a filter of three colors of red, green, and blue as in the prior art, and does not use a light emitting means for emitting three wavelengths, and a blue light emitting means for emitting blue light. A full color can be created using only light and only green and red filters containing a fluorescent material, resulting in a color liquid crystal display device with low power consumption and high image quality, and simplification of the manufacturing process of the device. It will be possible.

Further, in general, the coloring by the blue fluorescent material is not sufficient as compared with the other colors, so that the blue coloring is directly performed without using the blue color filter like the present apparatus. It is advantageous to use blue light according to.

According to a second aspect of the invention, there is provided a first substrate, which is a first transparent substrate on which a color filter and transparent electrodes are sequentially laminated, and a first substrate, which is arranged so as to face the first substrate, A second substrate formed of a second transparent substrate on which an active matrix array including pixel electrodes arranged in a matrix is formed; a liquid crystal layer enclosed between the first substrate and the second substrate; A light emitting means disposed on the opposite side of the second substrate from the liquid crystal layer;
Excited by receiving a light in a wavelength region other than the required wavelength region and a transmissive material layer that transmits light in the required wavelength region and absorbs light in the other wavelength region, and needs A fluorescent material layer that emits light in the wavelength region, in the direction from the first transparent substrate to the second transparent substrate,
A color liquid crystal display device is characterized in that the color liquid crystal display device is provided by laminating in this order.

With such a structure, the light emitted from the backlight first passes through the fluorescent material layer, so that the light having a wavelength in a predetermined region is transmitted and the other light is absorbed and the light is emitted. It excites the fluorescent material to emit the light of the desired color, and by its action it prepares the light with the wavelength limited to a certain extent, and secures the emitted light amount without reducing the transmitted light amount only by the transmissive / absorptive material. While
Next, the light is incident on and transmitted through the laminated transmissive / absorbent material layer. As described above, the transmissive / absorptive material is generally inferior to the fluorescent material in the amount of transmission, but is superior in the vividness of coloring. In this way, the color filter composed of the two layers can efficiently create a desired color while securing the transmission amount of the color to be expressed. Then, a desired color created by controlling the mixing ratio of the three colors of red, green and blue can be created while suppressing the reduction in the brightness of the display screen.

Further, in the color liquid crystal display device according to claim 2, the light emitting means may emit only blue light, and the color filter may include only a red filter and a green filter (claim 3). ). With such a configuration, the fluorescent liquid crystal and the color filter can be made simpler while substantially full color is possible in the color liquid crystal display device according to claim 2, and the manufacturing process and the structure of the device itself can be simplified. Can be transformed.

According to a fourth aspect of the present invention, there is provided a first substrate composed of a first transparent substrate on which a color filter and a transparent electrode are sequentially laminated inside, a first substrate which is arranged so as to face the first substrate, and a matrix is formed inside. A second substrate, which is a second transparent substrate on which an active matrix array including pixel electrodes is formed, a liquid crystal layer enclosed between the first substrate and the second substrate, and the second substrate. A light emitting means disposed on the opposite side of the substrate from the liquid crystal layer, wherein the color filter transmits light in a required wavelength range and absorbs light in other wavelength ranges. A color liquid crystal display device comprising: a material; and a fluorescent material that is excited by receiving light in a wavelength region other than the required wavelength region and emits light in the required wavelength region.

With such a structure, the color filter is formed as a simple layer, but the transmissive / absorptive material and the fluorescent material are mixed and contained in the layer so that they are excited by the fluorescent material. By transmitting the emitted light to the transmissive / absorptive material, the transmission amount can be effectively secured, and a clear image can be obtained by the transmissive / absorbent material. This is because the transmissive / absorptive material is generally inferior to the fluorescent material in the amount of transmission, but is superior in the vividness of the color as described above.

Further, in the color liquid crystal display device according to a fourth aspect, the light emitting means may emit only blue light, and the color filter may include only a red filter and a green filter. With such a configuration, in the color liquid crystal display device according to the fourth aspect, the fluorescent tube and the color filter can be made simpler to simplify the manufacturing process and the structure of the device itself.

A color filter for color liquid crystal display according to a sixth aspect is excited by receiving light in a wavelength region other than a required wavelength region by blue light emitted from a blue light emitting means, and the required wavelength region is excited. It is characterized in that only a red filter and a green filter each containing a material for emitting the light are provided as color filters. With such a configuration of the color filter, only the blue light by the blue light emitting means and only the green and red filters containing the fluorescent material are used without using the filters of the three colors of red, green and blue as in the prior art. Since it can be used to create a full color, it can maintain the sharpness of the screen with low power consumption and simplify the manufacturing process.

A color filter for color liquid crystal display according to a seventh aspect of the present invention includes a transmissive / absorptive material layer containing a transmissive / absorptive material that transmits light in a required wavelength range and absorbs light in other wavelength ranges. Characterized by comprising a laminate with a fluorescent material layer containing a fluorescent material that is excited by receiving light in a wavelength region other than the required wavelength region and emits light in the required wavelength region. .

With such a structure of the color filter, for example, when the fluorescent material is arranged on the side close to the backlight, the light emitted from the backlight is first passed through the fluorescent material layer, and The color expressed by the filter is converted into light with a wavelength limited to some extent by the action described above, and while being efficiently secured the amount of light to be transmitted, the light is emitted to and transmitted through the next layer of the transmissive / absorbent material. Can be created without waste. Then, a desired color created by controlling the mixing ratio of the three colors of red, green, and blue can be created while suppressing the reduction in brightness and ensuring the sharpness of the image quality. The two layers of the material are laminated in this order because the transmissive / absorbent material is generally inferior to the fluorescent material in the amount of transmission, but is superior in the vividness of color development.

A color filter for a color liquid crystal display device according to an eighth aspect includes a transmissive / absorptive material that transmits light in a required wavelength range and absorbs light in other wavelength ranges.
A fluorescent material that is excited by receiving light in a wavelength region other than the required wavelength region and emits light in the required wavelength region. With such a structure, the color filter is formed as a simple layer, and by mixing and containing the transmissive / absorptive material and the fluorescent material in the layer, the light emitted by the fluorescence is transmitted. It can be suitably used for the absorber to effectively secure the amount of light and obtain a clear image. This is because the transmissive / absorptive material is generally inferior to the fluorescent material in the amount of transmission, but is superior in the vividness of color development.

[0027]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

First Embodiment (Claim 1) FIG. 1 is a schematic sectional view showing a color liquid crystal display device according to the first embodiment. Reference numeral 1 in FIG. 1 is a color liquid crystal display device (hereinafter, referred to as liquid crystal). It is abbreviated as a display device). Describing the reference numerals further, 2 is a first substrate and 4 is a first substrate.
Transparent substrate, 5 is a polarizing plate on the output side, 7R is a red color filter, 7G is a green color filter, 8 is a black mask, 9 is a window portion, 10 is a transparent electrode (ITO), 11 is a liquid crystal layer, and 14 is a second Substrate, 15 is second transparent substrate, 16 is pixel electrode, 18 is incident side polarization plate, 20 is blue fluorescent tube, arrow BL is blue backlight, arrow B is blue emitted light, arrow G
Indicates green emitted light, and arrow R indicates red emitted light.

The liquid crystal display device 1 has a planar shape that spreads in the left-right direction of the drawing and in the direction perpendicular to the paper surface, and the first substrate 2 constitutes the display surface of the device, and the outside thereof, that is, FIG. In, the user visually recognizes the display surface from the upper side. The device 1 includes a second substrate 1 arranged to face the first substrate 2.
4 and these first and second substrates (2 and 1
The liquid crystal layer 11 is inserted between 4).

The first substrate 2 includes a first transparent substrate 4 having a light transmitting property, and the second substrate 14 includes a second transparent substrate 15. The first and second transparent substrates (4, 15) are made of glass, quartz, resin or the like and have an insulating property. That is, between the first and second transparent substrates (4, 15),
A liquid crystal layer 11 filled with liquid crystal is formed. The liquid crystal is, for example, a nematic type, and is a mixture of several kinds of phenylcyclohexane compounds (including a —CN / —F group).

A green color filter 7G, a red color filter 7R, and a black mask 8 are provided on the inner surface of the first transparent substrate 4 (that is, the surface on the liquid crystal 11 side). The color filter is generally made of acrylic resin or the like. These color filters (7G, 7
R) contains a fluorescent material as described later. What should be noted here is that the blue filter is not provided at the position where the blue filter is generally provided. The portion is referred to as the window portion 7W here.

Here, the green light filter 7G in the color filter of the present embodiment transmits light in the green wavelength region and absorbs light in the other wavelength regions, and the action of the fluorescent substance causes the green wavelength to be absorbed. A material that emits green light by being excited by receiving light in a wavelength region (including invisible light region) other than the region is included. Examples of the green light filter include, for example, a solution of uranium dye in a concentration of 1 to 4%, a melamine resin, an acrylic resin, and a urea resin, and the dye is fixed in a resin polymerization process to form a fluorescent pigment. It was dispersed in.

Similarly, the red light filter 7R transmits light in the red wavelength region and absorbs light in the other wavelength regions, and the action of the fluorescent material causes the wavelength region other than the red light wavelength region ( It includes a material that is excited by receiving light of a non-visible light region) and emits red light. As the red light filter, for example, a rhodamine B-based dye and an eosin-based dye are made into a solution having a concentration of 1 to 4%, and melamine resin, acrylic resin, urea resin, etc. are added and the dye is fixed in the resin polymerization process to obtain a fluorescent pigment. Further, the one dispersed in acrylic resin was used.

Red and green color filters (7R, 7
G), the window 7W, and the first transparent substrate 4 are covered with the transparent electrode 10 made of ITO (indium tin oxide) or the like.

On the inner surface of the second transparent substrate 15, that is, the surface on the liquid crystal 11 side, an active matrix array including a liquid crystal drive section having a switching element and a TFT (thin film transistor) for controlling the switching element and a pixel electrode 16. (Not shown) is provided. The pixel electrode 16 is laminated on the second transparent substrate 15 so as to face the window portion 7W provided at the place where the red filter 7R, the green filter 7G, and generally the blue filter should be provided. There is.

The black mask 8 is formed, for example, by forming a film of metallic chromium by a sputtering method, and has the purpose of improving contrast and preventing color mixture of colorants. But,
It may be omitted depending on the case.

An alignment film (not shown) is provided on each of the transparent electrode 10 and the pixel electrode 16 (that is, the surface on the liquid crystal side). The alignment film is formed of polyimide resin or the like, and the surface thereof is subjected to rubbing treatment or the like to form the alignment direction, and the liquid crystal molecules of the liquid crystal layer 11 are aligned. However, if the alignment film is not required due to the structure, it may be omitted.

Next, the operation of the liquid crystal display device 1 will be described. A blue fluorescent tube 20 as a light emitting means, that is, a backlight.
Is disposed on the side of the incident side polarization plate 18 laminated on the second substrate 14 opposite to the first transparent substrate. Blue fluorescent tube 2
0 emits only blue light. The blue backlight BL emitted from the fluorescent tube passes through the incident side polarization plate 18 and the second transparent plate 15 and enters the liquid crystal layer 11. The blue incident light is controlled by each pixel electrode 16 to have a desired intensity and is incident on each of the color filters 7R and 7G and the window 7W. The incident light is emitted by the red filter 7R and the green filter 7R in a color peculiar to the fluorescent substance contained therein. That is, the red color filter 7R
Is excited by receiving light in a wavelength region other than the required wavelength region, and includes a fluorescent material that emits light in the required wavelength region, so that the blue light is absorbed and excited to emit red light. discharge.

This effect is the same for the green color filter 7G. That is, the green color filter 7G is
It contains a fluorescent material that is excited by receiving light in a wavelength range other than the required wavelength range and emits light in the required wavelength range, and thus absorbs and excites the blue light to emit green light. .

It is known that the responsiveness of the fluorescent material is sufficiently fast for a general liquid crystal display screen, and the delay of response does not pose a problem.

As the blue fluorescent tube, ultraviolet rays around 253.7 nm emitted from Hg atoms excited by electric discharge in a fluorescent tube filled with Hg-Ar gas fluoresce the fluorescent material coated in the glass tube and become blue visible. I used a type that converts light. Further, as the blue phosphor, B
aMg ₂ Al ₁₆ O ₂₇ / Eu, 3 (SrCaBa) ₃
(PO ₄ ) ₂ / Eu, and (SrCaBa) 10 (P
O ₄ ) ₆ C ₁₂ B ₂ O ₃ / Eu was used.

FIG. 2 is a graph showing the spectral characteristics of the red and green color filters. A solid line represents the transmittance when using a normal transmissive absorption type color filter, and a broken line represents the transmittance when using a color filter using a fluorescent material. G is a green transmissive type filter and R is a red transmissive type filter. , G'represents the characteristics of green and R'represents the characteristics of a red fluorescent material filter.

The permeation absorbing material used in FIG.
Pigment ink is used, red is a dianthraquinone pigment ink, and green is a halogenated phthalocyanine pigment ink. Those obtained by dispersing these pigments in an acrylic resin were used. The red and green fluorescent materials are as described above. From this graph, the red and green fluorescent materials are about 20% and 50% less than the absorbing and transmitting materials, respectively.
It can be seen that the transmittance is increased by about%.

In the window portion 7W, the pixel electrode 16
The blue light transmitted through the liquid crystal layer 11 whose intensity is determined by being controlled by is transmitted as it is, so that the required intensity is secured. As will be described later, the window portion 7W has the same function as the blue filter. With the above configuration, the three primary colors can be created substantially by the configuration of only the green and red filters without providing color filters for all three primary colors, and the transmittance of emitted light can be increased.

At this time, the pixel electrode 16 determines the intensity according to the ratio of each of the three primary colors, and the three primary colors form a set and the color mixture determined by the ratio is visually recognized as one color. . Thus, the three lights that should be visually recognized as one desired color are formed. After that, the light enters the first transparent substrate 4, passes through the exit side polarization plate 19, exits from the liquid crystal device, and is visually recognized.

Here, in this embodiment, there is no blue filter, and the window portion 7W is provided in that portion. The reason why there is no blue filter is that the light originally emitted by the light emitting means is blue light, and thus the filter means that needs coloring is not necessary. In general, the color generated by the blue fluorescent material is not sufficient as compared with the other colors, so the blue color is not directly emitted from the blue light emitting means without using the blue color filter as in the present device. It is very effective to use.

In the liquid crystal display device according to the present embodiment, substantially full color can be created by using only the light emitting means for only blue light and the green and red filters containing the fluorescent material. Therefore, both the light emitting means and the color filter have a simpler structure than the conventional example, so that the manufacturing process can be simplified and the manufacturing cost can be reduced. Moreover,
Since a fluorescent material is used, a high quality display screen can be provided while reducing power consumption.

Second Embodiment (Claim 2) FIG. 3 shows a color liquid crystal display device 10 according to the second embodiment.
It is a schematic cross section which shows 1. Only the parts different from those in FIG. 1 are denoted by reference numerals, 107r is a red pigment color filter, 107R is a red fluorescent color filter, 107g is a green pigment color filter, 107G is a green fluorescent color filter, and 107b is a blue pigment color filter. 1
07B is a blue fluorescent color filter, 120 is a light emitting means, arrow D is white incident light, and arrow B is blue emitted light.

The liquid crystal display device 101 has a first substrate 2 and a second substrate 14 arranged to face the first substrate 2, and these first and second substrates (2 and 14) are provided. The liquid crystal layer 11 is filled in between. The first substrate 2 includes a first transparent substrate 4 having a light-transmitting property, and the second substrate 14 is a second transparent substrate.
Transparent substrate 15. That is, the liquid crystal is filled between the first and second transparent substrates (4, 15).
Is formed. A color filter and a black mask 8 are laminated and provided on the inner surface of the first transparent substrate 4 (that is, the surface on the liquid crystal 11 side).

Here, the color filter of this embodiment has two layers. That is, for each of the three colors of green, red, and blue as described above, the pigment color filter layer (transmissive / absorptive material layer) and the fluorescent color filter are sequentially arranged from the inner surface (that is, the liquid crystal side) of the first transparent substrate 4. A layer (fluorescent material layer) is laminated. These are 3 layers of green, red and blue, each consisting of 2 layers.
A desired color is created by emitting a set of one light in color from the liquid crystal panel. Regarding red and green, the transmissive / absorptive material and the fluorescent material are as described above.

For blue, a phthalocyanine pigment ink was used as the transmissive material.

As the blue fluorescent material, a diaminostilbene dye is made into a solution having a concentration of 1 to 4%, and a melamine resin, an acrylic resin, a urea resin, and the like are added, and the dye is fixed in the resin polymerization process to form a fluorescent pigment. It was used after being dispersed in a resin. A blue fluorescent filter was formed by applying it on a glass substrate.

Although a general three-wavelength white light tube is used as the light emitting means, a monochromatic light tube such as an ultraviolet light tube or a blue light tube may be used. Moreover, you may use LED etc.

With such a structure, the light emitted from the fluorescent tube is converted into the light whose wavelength range is limited to some extent by first passing through the fluorescent material layer. That is,
While transmitting only a certain range of light by the transmission and absorption function of the fluorescent material layer, at the same time, the fluorescent material is excited by using the light of the other wavelength range, and one of the desired three primary colors is selected. It emits and emits the light that it represents. In this way, the light is emitted to the next pigmented color filter while narrowing the wavelength region and securing an apparent light amount. In this way, the fluorescent material is converted in advance into light that includes a large wavelength range of the color that the pigment filter transmits, and then passed through the pigment filter to reduce waste and create the desired color. can do. Then, it is possible to create a desired color by mixing colors created by a mixing ratio of three colors of red, green, and blue while preventing the reduction in brightness and increasing the sharpness of color development. The fluorescent filter for blue light, which is not used in the first embodiment, is used in the second embodiment.

FIG. 4 is a graph showing the spectral characteristics of the color filter. B, G, and R respectively represent the transmittance of a color filter using a blue-green-red transmissive / absorptive material,
B ', G', and R'represent the transmissivities of the color filters using the blue-green-red fluorescent material, respectively. It can be seen from FIG. 4 that the color filters using green, red, and blue fluorescent materials have transmittances increased by about 50%, 20%, and 50%, respectively. The three-color transmissive / absorptive material and the fluorescent material are as described above.

At this time, the pixel electrode 16 visually creates one mixed color. After that, the light enters the first transparent substrate 4, passes through the exit side polarizing plate 5, and exits from the liquid crystal device,
It is visually recognized by the viewer. Further, in the present embodiment, the light emitting means may emit only blue light, and the color filter may include only a red filter and a green filter (claim 3). With such a structure, the structure of the fluorescent tube and the color filter can be simplified, and the manufacturing process and the structure of the apparatus itself can be simplified.

Third Embodiment (Claim 4) FIG. 5 shows a color liquid crystal display device 20 according to the third embodiment.
It is a schematic cross section which shows 1. Numerals 207rR are red color mixing color filters (described later), 207gG is a green color mixing filter, and 207bB is a blue color mixing filter.

The liquid crystal display device 201 has a first substrate 2 and a second substrate 14 arranged so as to face the first substrate 2, and these first and second substrates (2 and 14) are provided. The liquid crystal layer 11 is filled in between. The first substrate 2 includes a first transparent substrate 4 having a light-transmitting property, and the second substrate 14 includes a second transparent substrate 15 having a light-transmitting property. On the inner surface of the first transparent substrate 4 (that is, the surface on the liquid crystal 11 side), the green compound color filter 207gG, the red compound color filter 207rR, the black mask 8, and the blue compound color filter 207bB are provided.

These prepared color filters of this embodiment contain a transmissive / absorptive material and a fluorescent material. The ratio of transmissive / absorptive material and fluorescent material, the method of blending,
The liquid crystal display device can be appropriately selected according to the use and purpose. These color filters form a set of three colors of green, red, and blue, respectively, and the three colors which appear as light of one color visually due to color mixture are emitted from the liquid crystal panel to create a desired color.

As the arc tube 120, a general three-wavelength white light tube (fluorescent tube) is used, but a monochromatic light tube such as an ultraviolet tube may be used. Moreover, you may use LED etc.

The operation of this embodiment will be described. Fluorescent tube 120
The outgoing light D emitted from passes through the liquid crystal layer 11 and enters each color filter, where it collides with the pigment material and the fluorescent material. For example, when colliding with the red color mixture filter 207rR, the transmissive / absorptive material contained therein transmits the light in the red wavelength region and absorbs the other light. The light absorbed here is mainly converted into heat and does not contribute to the brightness of the liquid crystal display. On the other hand, when the emitted light D from the fluorescent tube collides with the fluorescent material, the light in the constant wavelength region of red is transmitted, and the light in the constant wavelength region other than that excites the fluorescent material. It emits a period or red light. The same applies to the green and blue blending filters.

By the above action, the desired light transmitted through the transmissive / absorbent material, the light transmitted through the fluorescent material, and the desired light emitted by being absorbed / excited by the fluorescent material are combined, The light is emitted from the color filter having the compounded material layer. The light thus combined and emitted is, as apparent light, emitted from the first transparent substrate with an increased luminous intensity as compared with the filter made of only the pigment material, and is visually recognized by the viewer of the image. Then, the set of colors created by the ratio of the three colors of red, green, and blue is visually recognized as one desired color, and a bright image is provided.

Since the constitution of this embodiment is a color filter in which a pigment material and a fluorescent material are mixed to form one layer, it is simpler than the constitution in which it is divided into two layers as in the second embodiment. Can be configured as

Here, it is also possible to use a single light color such as blue or ultraviolet for the fluorescent tube. LEDs can also be used.

Further, in the present embodiment, the light emitting means may emit only blue light, and the color filter may include only a red filter and a green filter (claim 5). With such a structure, the structure of the fluorescent tube and the color filter can be simplified, and the manufacturing process and the structure of the apparatus itself can be simplified.

Fourth Embodiment (Claim 6) FIG. 6 is a partial view of FIG. 1 showing a color filter for a color liquid crystal display device according to a fourth embodiment. The reference numerals in FIG. 6 are the same as those in FIG. The color filter for a color liquid crystal display device according to the fourth embodiment is the color filter portion in the color liquid crystal display device according to the first embodiment. The configuration and operation of the color filter are the same as those of the color liquid crystal display device according to the first embodiment.

By configuring the color filter as described above, it is possible to use only the blue light emitting means without using the light emitting means for white light and the filters for three colors of red, green and blue as in the conventional case, as already described in detail. Full color can be created using only blue light and green and red filters containing fluorescent materials, thus providing a bright screen with low power consumption and simplifying the manufacturing process.

Fifth Embodiment (Claim 7) FIG. 7 is a schematic partial view of FIG. 3 showing a color filter for a color liquid crystal display device according to a fifth embodiment. The reference numerals in FIG. 7 are the same as those in FIG. The color filter for a color liquid crystal display device according to the fifth embodiment is the color filter portion of the color liquid crystal display device according to the second embodiment. The structure and operation of the color filter are the same as those of the color filter portion of the color liquid crystal display device according to the second embodiment.

However, the order of laminating the transmissive / absorptive material layer and the fluorescent material layer can be appropriately selected according to the intended use and purpose of the liquid crystal screen.

When the color filter is constructed as described above, the light emitted from the backlight is first passed through the fluorescent material layer to be converted into the light whose wavelength is limited to some extent by the above-mentioned fluorescent action, In addition, the light of the color represented by the filter can be created without waste by emitting the light to the next layer of the transmissive / absorbent material and transmitting it together with the amount of light to be transmitted. Then, a desired color created by controlling the ratio of the three colors of red, green, and blue can be created while suppressing the reduction in brightness and maintaining the sharpness of the image quality. The two layers of the material are laminated in this order because the transmissive / absorptive material is generally inferior to the fluorescent material in the amount of transmission as described above, but is superior in the vividness of coloring.

However, the transmissive / absorptive material layer and the fluorescent material layer may be arranged in the reverse order depending on the purpose of use or desired liquid crystal screen and device characteristics.

Sixth Embodiment (Claim 8) FIG. 8 is a partial view of FIG. 5 showing a color filter for a color liquid crystal display device according to a sixth embodiment. The reference numerals in FIG. 8 are the same as the reference numerals in FIG. The color filter for a color liquid crystal display device according to the sixth embodiment is the color filter portion in the color liquid crystal display device according to the third embodiment. The structure and operation of the color filter are the same as those of the color liquid crystal display device according to the third embodiment.

By configuring the color filter as described above, the transmissive / absorptive material and the fluorescent material are mixed in the layer while the color filter is a simple layer as already described in detail. By including it, the light emitted by the fluorescence can be suitably used for the transmission / absorption agent, the amount of light can be effectively secured, and a clear image can be obtained. This is because the transmissive / absorptive material is generally inferior to the fluorescent material in the amount of transmission, but is superior in the vividness of color development.

Of course, the present invention is not limited to the above-mentioned first to sixth embodiments.
For example, in the present embodiment, a fluorescent tube is described as the light emitting means, but the light emitting means is not limited to this.
Other means such as ED are applicable.

[0075]

As described in detail above, according to the color liquid crystal display device of the present invention, the following effects can be obtained.

That is, the color liquid crystal display device according to the first aspect does not use a filter of three colors of red, green, and blue as in the prior art, and does not use a light emitting means that emits light of three wavelengths. Full color can be created using only light and only green and red filters containing fluorescent materials. Further, in general, the color development by the blue fluorescent material is not sufficient compared with other colors, so it is not necessary to directly use the blue light by the blue light emitting means without using the blue color filter unlike this device. It is effective. Therefore, a color liquid crystal display device with low power consumption, high image quality, and a simple manufacturing process can be provided.

Further, in the color liquid crystal display device according to the second aspect, the light emitted from the backlight is first passed through the fluorescent material layer to transmit the light having a wavelength in a predetermined region,
And it absorbs other light and excites the fluorescent material to emit light of a desired color, and prepares it as light having a limited wavelength to a certain extent, without reducing the amount of transmitted light as much as that of the transmissive material alone. Then, the light is incident on the layer of the transmissive / absorbent material that is laminated next and is transmitted. Thus, a desired color can be created while securing the amount of transmitted light of the color to be expressed, and a color liquid crystal display device with low power consumption and high image quality can be provided.

In the color liquid crystal display device according to the fourth aspect, the color filter is formed as a simple layer, but by incorporating the transmissive / absorptive material and the fluorescent material in the layer, the color filter absorbs the fluorescent material. By making the light that is excited and emitted and the light that has been transmitted enter the transmissive / absorptive material, the transmission amount can be effectively secured, and a clear image can be obtained by the transmissive / absorbent material.

A color filter for a color liquid crystal display device according to a sixth aspect of the present invention, as a color filter means for creating a desired color, receives and excites blue light emitted from a blue light emitting means to emit light in a required wavelength range. Can be provided with only a red filter and a green filter that include a material that emits light. With such a configuration of the color filter, the sharpness of the screen can be maintained with low power consumption, and the manufacturing process can be simplified.

In the color filter for a color liquid crystal display device according to a seventh aspect of the present invention, the light emitted from the backlight is first converted into fluorescent light by forming a structure in which the transmissive / absorbent material layer and the fluorescent material layer are laminated. By converting the wavelength to a certain limited amount of light by passing through the conductive material layer, and efficiently securing the amount of light to be transmitted, and by emitting and transmitting the light to the next transmission / absorption material layer, The color represented by the filter can be created without waste. Thus, a clear and high-quality color filter can be provided.

In the color filter for color liquid crystal display according to claim 8, the color filter is a simple one layer,
By mixing and containing a transmissive / absorbent material and a fluorescent material in the layer, the light emitted by the fluorescence is applied to the transmissive / absorbent agent to effectively secure the amount of light, and a clear image can be obtained. Obtainable.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view of a color liquid crystal display device according to a first embodiment of the present invention.

FIG. 2 is a graph showing a spectral characteristic of a filter material.

FIG. 3 is a schematic sectional view of a color liquid crystal display device according to a second embodiment of the present invention.

FIG. 4 is a graph showing a spectral characteristic of a filter material.

FIG. 5 is a schematic sectional view of a color liquid crystal display device according to a third embodiment of the present invention.

FIG. 6 is a partial view of FIG. 1 showing a color filter for a color liquid crystal display device according to a fourth embodiment of the present invention.

FIG. 7 is a partial view of FIG. 3 showing a color filter for a color liquid crystal display device according to a fifth embodiment of the present invention.

FIG. 8 is a partial view of FIG. 5 showing a color filter for a color liquid crystal display device according to a sixth embodiment of the present invention.

FIG. 9 is a schematic cross-sectional view showing a conventional color liquid crystal display device.

[Explanation of symbols]

1, 101, 201 ... Color liquid crystal display device, 2 ... First substrate, 4 ... First transparent substrate, 5 ... Emitting side polarizing plate, 7G ... Green color filter, 7R ... Red color filter, 7W ...
Window, 8 ... Black mask, 10 ... Transparent electrode (IT
O), 11 ... Liquid crystal layer, 14 ... Second substrate, 15 ... Second transparent substrate, 16 ... Pixel electrode, 18 ... Incident side polarization plate, 20 ...
Blue fluorescent tube, 107b ... Pigment blue filter, 107B
... Fluorescent blue filter, 107g ... Pigment green filter, 107G ... Fluorescent green filter, 107r ... Pigment red filter, 107R ... Fluorescent red filter, 120
... Light emitting means, 207bB ... Mixed blue color filter, 2
07gG ... Compound green color filter, 207rR ... Compound red color filter, B, B '... Blue light, G, G' ... Green light, R, R '... Red light, BL ... Blue backlight

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) G09F 9/35 G09F 9/35 F term (reference) 2H048 BA01 BA02 BB02 BB03 BB04 BB44 CA01 CA04 CA14 CA19 CA21 CA22 CA23 2H091 FA02Y FA41Z FA43Y FB02 FB12 GA16 LA03 LA15 5C094 AA02 AA08 AA22 AA43 BA43 CA19 CA24 DA13 EA04 EA07 EB02 ED03 ED20 5G435 AA00 AA04 AA17 BB12 BB15 CC12 DD09 DD11 DD13 EE25 GG27 GG25 GG25

Claims (8)

[Claims] 1. A first substrate composed of a first transparent substrate in which a color filter and a transparent electrode are sequentially laminated inside, and pixel electrodes arranged to face the first substrate and arranged in a matrix inside. A second substrate formed of a second transparent substrate on which an active matrix array including a liquid crystal layer, a liquid crystal layer enclosed between the first substrate and the second substrate, and a liquid crystal layer of the second substrate. And a blue light emitting means disposed on the opposite side, wherein the color filter is excited by receiving light in a wavelength range other than the required wavelength range, and a material that emits light in the required wavelength range. , A color liquid crystal display device comprising only a red filter and a green filter, respectively. 2. A first substrate composed of a first transparent substrate in which a color filter and a transparent electrode are sequentially laminated inside, and pixel electrodes arranged to face the first substrate and arranged in a matrix inside. A second substrate formed of a second transparent substrate on which an active matrix array including a liquid crystal layer, a liquid crystal layer enclosed between the first substrate and the second substrate, and a liquid crystal layer of the second substrate. And a light emitting means disposed on the opposite side, wherein the color filter transmits a light in a required wavelength range and absorbs light in a wavelength range other than that, and a transmissive / absorbent material layer, Excited by receiving light in a wavelength range other than the wavelength range, and a fluorescent material layer that emits light in a required wavelength range, in the direction from the first transparent substrate to the second transparent substrate, Be prepared by stacking in this order Color liquid crystal display device according to claim. 3. The color liquid crystal display device according to claim 2, wherein the light emitting means emits only blue light, and the color filter includes only a red filter and a green filter. 4. A first substrate, which is a first transparent substrate in which a color filter and a transparent electrode are sequentially laminated inside, and pixel electrodes which are arranged to face the first substrate and are arranged inside in a matrix. A second substrate formed of a second transparent substrate on which an active matrix array including a liquid crystal layer, a liquid crystal layer enclosed between the first substrate and the second substrate, and a liquid crystal layer of the second substrate. And a transmissive / absorptive material that transmits light in a required wavelength range and absorbs light in other wavelength ranges, and A color liquid crystal display device comprising: a fluorescent material that is excited by receiving light in a wavelength region other than the wavelength region and emits light in a required wavelength region. 5. The transmissive color liquid crystal display device according to claim 4, wherein the light emitting means emits only blue light, and the color filter includes only a red filter and a green filter. 6. A red color containing a material that is excited by receiving light in a wavelength range other than the required wavelength range by blue light emitted from the blue light emitting means and emits light in the required wavelength range. A color filter for a color liquid crystal display, comprising only a filter and a green filter as a color filter. 7. A transmissive / absorptive material layer containing a transmissive / absorptive material which transmits light in a required wavelength region and absorbs light in other wavelength regions, and A color filter for color liquid crystal display, comprising a fluorescent material layer containing a fluorescent material, which is excited by receiving light and emits light in a required wavelength region, in a laminated manner. 8. A transmissive material that transmits light in a required wavelength range and absorbs light in other wavelength ranges, and is excited by receiving light in a wavelength range other than the required wavelength range. And a fluorescent material that emits light in a required wavelength range, and a color filter for color liquid crystal display.